DE20102047U1 - Locking system with transponder key - Google Patents

Description

Technical area

The innovation concerns a locking system consisting of a mechanical locking unit and an electronic locking unit coupled to the locking unit, whereby the electronic locking unit can be locked contact-free with a coded transponder key.

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State of the art

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Locking systems are used to lock doors, cupboard doors, drawers and the like in order to prevent unauthorized entry or access. There are mechanical locking systems consisting of a locking and locking unit. The locking unit is made up of a locking mechanism that locks the door or drawer. In addition to the usual mechanics, the locking unit consists in particular of a locking cylinder into which a suitable key is inserted to operate it. There are so-called locking systems for such locking systems. These locking systems consist of several locking systems.

In such locking systems, which are often used in large buildings, all locking systems can be operated with a single key. This key

is also called a "master key". Other keys can only open or close certain locking systems. This can ensure that certain areas of the building can be accessed with this locking system and others cannot.
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Electronic locking systems with transponder keys are also known. Electronic locking systems can also be part of a locking system. These locking systems no longer have a conventional mechanical locking unit, but an electronic one. The electronic locking unit is often located in a knob of the locking system. The electronics are opened and closed using a transponder key. The electronics of the locking unit must be constantly supplied with electrical voltage. At present, locking systems are usually wired to the power grid for this purpose. The disadvantage of wiring, however, is the complex installation. Batteries or rechargeable batteries can also be provided as an alternative. However, locking systems with batteries can only lock a relatively small number of times. The electronics are in a constant state of readiness to check whether a valid transponder key requires a lock. This quickly drains the batteries.

The known transponder keys have a chip with a unique code that can be read via radio or, if necessary, via infrared radiation. The transponder key can be designed as an active or passive element, whereby the active transponder key requires its own power supply.

The known electronic locking systems are not suitable for easily converting an existing conventional mechanical locking system because they are designed to be installed inside the knob.

Revelation of innovation

The aim of the innovation is therefore to avoid the disadvantages that arise with the state of the art and, in particular, to create a locking system that allows more locking operations than was previously possible, independent of the power grid.

According to the innovation, the object is achieved in that, in a locking system of the type mentioned at the beginning, a magnet is provided in the transponder key for activating the electronic locking unit.

The innovation is based on the principle of keeping the energy consumption of the locking electronics as low as possible in order to enable many locking processes. To achieve this, the electronics of the locking system may only consume electrical energy when activated. The electronics are switched off after activation. The electronics are only activated by electromagnetic interactions when a magnet is brought so close to the locking system that the magnetic field is sufficient to activate the electronics. Since the magnetic field can penetrate a large number of materials, the electronics or the electrical locking unit can be housed in a well-concealed location. When the electrical locking unit is activated, the coding of the - usually passive - transponder key is queried, for example by radio. If the coding is correct, the locking system can be operated.

It has proven to be an advantageous embodiment of the innovation if the magnet of the transponder key is designed as a permanent magnet. This avoids the need for the transponder key to also be supplied with electrical energy.

Advantageously, the electronic locking unit is switched off again at a predetermined time interval after activation in order to reduce the energy consumption of the electronics to a minimum.

Thanks to a modular design, the electronic locking unit can be designed in such a way that it can be provided on corresponding mechanical locking units. This allows an existing, completely mechanical locking system to be

The electronic locking unit can be converted in the simplest way. In an advantageous embodiment, the electronic locking unit controls a mechanical locking mechanism that engages in the locking unit. It has also proven to be advantageous if the locking mechanism has at least one locking ball that blocks the locking unit. The locking ball is then guided in a suitable manner in a guide system. The locking ball is moved by an electromagnetic drive that is controlled by the locking electronics. In a preferred embodiment, this electromagnetic drive is designed as a lifting magnet. This converts a minimum lifting force into a maximum holding force without subjecting the bolt of the lifting magnet to shear stress.

In a further advantageous embodiment of the innovation, a programming transponder is provided which authorizes the user of this transponder to program the locking system. This programming transponder also serves to authorize other transponder keys to operate the locking system.

In order to make the electronics as simple as possible to design and program, the locking electronics have a processor and a memory.

To ensure independence from the rest of the power grid, the innovation in a preferred embodiment has its own energy storage device to supply the locking electronics. This can be a battery or an accumulator, for example.

To ensure that the battery is not used up before the last operation is possible, an energy monitoring system is provided to monitor the energy storage. The energy monitoring system generates a visual and/or acoustic signal to indicate when the battery charge is nearing its end.

Further advantages arise from the subject matter of the dependent claims. 30

Short description of the drawing

Fig. 1 shows the schematic diagram of an innovative locking system in a

Side view.
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Fig. 2 shows the schematic diagram of an innovative locking system in a

Front view.

Fig.3 shows a passive transponder key with a permanent magnet.

Fig.4 shows a sectional view E-F according to Fig. 5 of an innovative

locking unit.

Fig. 5 shows a sectional view A-B according to Fig. 4 of an innovative

locking unit.

Fig.6 shows a sectional view C-D according to Fig. 5 of an innovative

locking unit.

Fig.7 shows a detailed view of the locking mechanism of an innovative

Locking unit in open position.

Fig.8 shows a detailed view of the locking mechanism of an innovative

Locking unit in closed position.

Preferred embodiment

In Fig. 1, 10 denotes a locking system according to the innovation. In this

In the embodiment, the locking system 10 consists of a mechanical

Locking unit 12, an electronic locking unit 14 and a

Transponder key 16. The transponder key 16 is shown in Fig. 3. The

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Mechanical locking unit 12 consists of bolts 18, 20, 22. The bolts 20 and 22 are connected to the locking unit 12 in a known manner via rods 24, 26. The rods 24, 26 are in turn rotatably mounted on a cabinet door (not shown) using fastening means 28, 30. The bolt 18 is directly connected to the locking unit 12. The locking unit 12 has coupling elements 32 which synchronously couple the various bolts to one another. When a knob 34 is operated, the bolts 18, 20, 22 are brought into the open or closed position. The locking electronics 14 are directly connected to the mechanical locking unit 12. A locking mechanism 36, as can be clearly seen in Figures 4 and 6, engages the mechanical locking unit 12 and prevents or allows the knob 34 to be operated. An antenna 38 is located in the electronic locking unit 14. The antenna 38 is used to read a code from the transponder key 16 via radio. The electronics of the locking system 10 are also activated via a magnetically actuated wheel switch, which is positioned centrally in the antenna 38.

The locking unit 12 and the closing unit 14 each have housings 40 and 42. The housings 40, 42 are made of a stable, but preferably lightweight material, such as steel or Zamak. The electronic locking unit 14 also has a switch 44 with which the locking electronics can be brought to a basic state when activated. The locking system 10 is screwed to a door via holes 46, 48.

Fig. 2 shows the schematic diagram of an innovative locking system 10 in a front view. The same components are designated as in the previous figure 1. The locking system 10 is screwed onto a cabinet door 50 as an example. The bolts 20 and 22, hinged by the rods 24 and 26, respectively, each engage around pins (not shown) for locking. The bolts 20, 22 are semi-circular for this purpose. The rods 24 and 26 are guided in fastening means 28, 30 to the appropriate holder. Rubber rings 52, 54 prevent slipping off the knob 34. The bolt 18 engages in a cavity (not shown) in the cabinet for locking.

Fig.3 shows a passive transponder key 16 with a permanent magnet 56. The transponder key 16 has a conical aluminum housing 58. At the upper end 59 of the aluminum housing 58 there is an eyelet 60 for a key chain. The lower end 62 is covered with a plastic cap 64. In the aluminum housing 58 of the transponder key 16 there is a coded transponder 66 which can be read by the locking electronics of the locking system 10.

Fig. 4 shows a sectional view E-F of a locking unit 14 according to the innovation. The same components have the same reference numerals here as they were used in previous figures. The antenna 38 is designed so that it fits into a corresponding standard hole in the door 50. The locking mechanism is designated by 36. The locking mechanism 36 engages directly in the locking mechanism of the locking unit 12 via a locking bolt 70 with a pin 72.

The locking mechanism 36 contains a lifting magnet 74 controlled by the locking electronics 88. The lifting magnet 74 is pointed on one side and pushes locking balls 76 apart in a guide 78 to lock until they reach recesses 81 in the locking slide 80 (see Fig. 8). The locking balls 76 now rest on the rod 82 of the lifting magnet 74. The locking slide 80, to which the locking bolt 70 is attached, can no longer move back and forth in the groove 84. To unlock, the rod 82 of the lifting magnet 74 is pulled out from between the locking balls 76. The locking balls 76 can now move in the guide 78 and release the locking slide 80, as is also shown in more detail in Fig. 7.

In the present embodiment, the locking and control electronics 88 contain a processor (not shown) with memory. A locking and test program runs through this. The processor also takes over all functional control and monitoring tasks that are possible for it. The electrical energy required for the electronics is drawn from a battery that is inserted in the battery compartment 86. The charge level of the battery is also monitored by the electronics. If a critical

When the charge level is reached, an optical and/or acoustic signal is emitted to alert the user so that a new battery can be inserted in time.

Fig. 5 shows a sectional view A-B of a locking unit 12 according to the invention.

Corresponding components have corresponding reference numerals, as in the previously described figures. The locking electronics 88 are connected to a battery via lines 90. The battery is connected to contacts 92 in the battery compartment 86 to supply voltage. The switch 44 can be used to return the control electronics 88 to a basic state.

Fig. 6 shows a sectional view CD of a locking unit 12 according to the invention. Corresponding components again have corresponding reference numerals as in the previously described figures.
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The basic functionality of an innovative locking system 10 is as follows:

The locking electronics 88 are at rest, i.e. they are completely switched off and do not use any electrical energy. As soon as the transponder key 16 with its magnet 56 comes close to the locking electronics 88, the electronics are activated via electromagnetic interaction. The locking electronics 88 now checks via radio whether the code of the transponder key 16 stored in the transponder 66 is "correct", i.e. whether the transponder key 16 is authorized to operate the locking system 10. If the code is correct, the lock is released. If the code is incorrect, the lock remains active. After the check, the locking electronics 88 switches off again until the next activation. The electronics 88 switches off after each locking process.

In order to program the locking electronics 88 to a specific transponder key, a special "master" or programming transponder is provided, which enables the user to program other transponder keys 16 to this electronics 88 of the

locking system 10. Such locking systems 10 can be components of entire locking systems that are not subject to any locking hierarchies.

Claims (15)

1. Locking system ( 10 ), consisting of a mechanical locking unit ( 12 ) and an electronic locking unit ( 14 ) coupled to the locking unit ( 12 ), wherein the electronic locking unit ( 14 ) can be locked contact-free with a coded transponder key ( 16 ), characterized in that a magnet ( 56 ) is provided in the transponder key ( 16 ) for activating the electronic locking unit ( 12 ). 2. Locking system ( 10 ) according to claim 1, characterized in that the magnet ( 56 ) is designed as a permanent magnet. 3. Locking system ( 10 ) according to one of claims 1 or 2, characterized in that means are provided which switch off the electronic locking unit ( 12 ) again after activation in a predetermined time interval. 4. Locking system ( 10 ) according to one of the preceding claims, characterized in that the electronic locking unit ( 12 ) is provided in a modular manner on the mechanical locking unit ( 10 ). 5. Locking system ( 10 ) according to one of claims 1 to 4, characterized in that the electronic locking unit ( 12 ) is provided in a concealed manner. 6. Locking system ( 10 ) according to one of claims 1 to 5, characterized in that the electronic locking unit ( 12 ) controls a mechanical locking mechanism ( 36 ) which engages in the locking unit ( 12 ). 7. Locking system ( 10 ) according to claim 6, characterized in that the locking mechanism ( 36 ) has at least one locking ball ( 76 ) which blocks the locking unit ( 12 ). 8. Locking system ( 10 ) according to one of claims 6 or 7, characterized in that a guide system ( 78 ) is provided for the locking ball ( 76 ). 9. Locking system ( 10 ) according to one of claims 6 to 8, characterized in that an electromagnetic drive ( 74 ) moves the locking ball ( 76 ). 10. Locking system ( 10 ) according to claim 9, characterized in that the electromagnetic drive is designed as a lifting magnet ( 74 ). 11. Locking system ( 10 ) according to one of claims 1 to 10, characterized in that a programming transponder is provided. 12. Locking system ( 10 ) according to one of claims 1 to 11, characterized in that the locking electronics ( 88 ) has a processor. 13. Locking system ( 10 ) according to one of claims 1 to 12, characterized in that the locking electronics ( 88 ) has a memory. 14. Locking system ( 10 ) according to one of claims 1 to 13, characterized in that an energy storage device is provided for supplying the locking electronics ( 88 ). 15. Locking system ( 10 ) according to claim 14, characterized in that an energy monitoring system is provided for monitoring the energy storage device.